Q34: Discuss the support of the accelerator community for your technology and to whatever extent your technology has outreach into other accelerator areas?

6/29/2004

K. Oide @ MEETING FIVE @ CALTECH

Table 1: SRF Facilities with SRF Infrastructure and Personnel Expertise

Europe USA ASIA

DESY for HERA, TTF- I and II Jlab for CEBAF and FEL KEK for TRISTAN, KEKB, J-Parc, TESLA

JAERI for FEL, ERL

CERN for LEP-II, LHC, and SPL (Superconducting Proton Linac)

Cornell for CESR, Neutrino Factory, Muon Collider

Beijing University for Ion Linac

INFN (Legnaro, Milano, Padova, Frascati) for the heavy ion linacs, proton linac,

Fermilab for Injector and Proton Linac

India NSC

Saclay (for SOLEIL) Argonne for ATLAS for heavy ions and RIA

Orsay (development and testing lab for couplers)

Michigan State University for RIA

BESSY for FEL development Los Alamos for Proton Linacs

Darmstadt (Operation of electron Linac for NP and FEL)

HEPL (Stanford Univ) for FEL

Rossendorf (SC FEL)

Table 2: Industries with SRF Infra Structure and SRF Capabilities

ACCEL, Germany

CERCA, France

Zanon, Italy

AES, USA

Meyer Tool, USA

Mitsubishi Heavy Industries, and Mitsubishi Electric, Japan

Nomura Plating, Japan

Table 3: New Laboratories Acquiring SRF technology

Europe USA

Daresbury for 4 GLS - Oak Ridge for SNS

SRRC, Taiwan Light Source

- Brookhaven for ERL Light Sources/RHIC cooling and collisions

Mumbai Proton Linacs

Table 4: Accelerator Facilities Acquiring Turnkey SRF modules from Industry and

Other Laboratories

Canadian Light Source

Swiss Light Source

ELETTRA (Trieste)

ESRF

DIAMOND ((UK)

BEPC (Beijing)

Korea ( LEP SC cavities for KOMAK)

Table 5: FEL and ERL Light Source Projects Under Development

USA Europe Asia

Jlab: FEL and ERL

Daresbury: 4 GLS and Prototype

KEK - ERL

Cornell: ERL BESSY: FEL

LBNL: LUX DESY: X-FEL

MIT: FEL INFN (Rome and Frascati) FERMI

BNL: PERL Saclay: ERL

Normal conducting linac

“Particle accelerators are also an essential part of the Nation‘s technical infrastructure for health care, for industry and for national security. One third of the 15,000 accelerators in operation worldwide are used in radiotherapy and almost two-thirds are used for industrial applications such as semiconductorproduction, sterilization and materials preparation or in processes such as x-ray micro-machining. Ultra-fast x-ray sources are being developed and used for nuclear stockpile stewardship, and accelerators are deployed for everyday use in noninvasive x-ray inspection of cargo containers.“

- The U.S. DOE Office of Science occasional paper

Normal conducting linac• Almost all commercial applications of accelerators an

d rf power use normal conducting technologies.• These applications generally do not require the high p

ower and high gradients used for a linear collider, but are concerned with cost, and often require compact products that can be easily transported or used in a constrained space.

• X-band radar systems driven by TWT amplifiers similar to those needed for the X-band collider are used on aircraft, ships, and satellites where space and weight are important considerations An example of one such use in NASA’s Mission to Planet Earth is given in reference [4].

X-band in Medical

“The next generation of high-energy linear accelerator will be based on X-band technology. The collateral technical opportunities for radiation oncology that will arise from Federal investments in this technology should not be missed. In principle, a new generation of linear accelerators should become available thatare roughly one-third as large as current systems. The first implementation of this technology is a self-contained intra-operative linear accelerator.”

- The U.S. National Cancer Institute report

X-band in Medical

• An X-band linear accelerator powered by a magnetron and delivering electron beams of 4-12 MeV, in the intra-operative Mobetron produced by Intraop and Siemens.

• The CyberKnife is produced by Accuray and distributed throughout the U.S. and Asia.

• An X-band linac with PPM klystrons, currently being developed for medical use at the National Institute of Radiological Sciences in collaboration with University of Tokyo and KEK, for Mobetron Inter-Operative Radiation Therapy (IORT) machine by Intraop and with Siemens Medical Systems.

• Stereotactic Radiosurgery at the Okayama Kyokuto Hospital in Okayama, Japan